Ontogeny of molecular forms of CCK-peptides in rat brain and gut

COOH-terminal immunoreactive cholecystokinin (iCCK) in methanol and acid extracts of brain and gut in the developing rat between 3 and 28 days after birth and in the adult has been fractionated on Sephadex G50. The single peak observed in methanol extracts of brain has an elution volume identical to that of CCK8. Acid extracts of brain contain only 10% as much iCCK as methanol extracts in a molecular form that appears to be a larger precursor because its elution volume on Sephadex is earlier than that of CCK33 or 39. Methanol extracts of duodenum at all ages contain a molecular form which is larger than CCK12 and about equal in abundance to CCK8. Acid extracts of rat duodenum contain 3 peaks: one elutes in the region of a previously described precursor form, CCK58; another co-elutes with CCK33 or 39; the third peak appears to be lower in molecular weight and is most prominent in the 2 week rat duodenum. Whether the larger iCCK found in methanol extracts or the smaller form found in acid extracts is derived from a common CCK precursor is yet to be determined.     

Activities of enzymes of ketone-body utilization in brain and other tissues of suckling rats

1. The activities of 3-hydroxybutyrate dehydrogenase and 3-oxo acid CoA-transferase in rat brain at birth were found to be about two-thirds of those of adult rat brain, expressed per g wet wt. The activities rose throughout the suckling period and at the time of weaning reached values about three times higher than those for adult brain. Later they gradually declined. 2. At birth the activity of acetoacetyl-CoA thiolase in rat brain was about 60% higher than in the adult. During the suckling period there was no significant change in activity. 3. In rat kidney the activities of the three enzymes at birth were less than one-third of those at maturity. They gradually rose and after 5 weeks approached the adult value. Similar results were obtained with rat heart. 4. The activity of glutamate dehydrogenase (a mitochondrial enzyme like 3-hydroxybutyrate dehydrogenase and 3-oxo acid CoA-transferase) also rose in brain and kidney during the suckling period, but at no stage did it exceed the adult value. 5. Throughout the suckling period the total ketone-body concentration in the blood was about six times higher than in adult fed rats, and the concentration of free fatty acids in the blood was three to four times higher. 6. It is concluded that the rate of ketone-body utilization in brains of suckling rats is determined by both the greater amounts of the key enzymes in the tissue and the high concentrations of ketone bodies in the blood. In addition, the low activities of the relevant enzymes in kidney and heart of suckling rats may make available more ketone bodies for the brain.     

Nicotinamide methylation tissue distribution,developmental and neoplastic changes

The distribution of cytosolic activity of nicotinamide:S-adenosylmethionine methyltransferase (nicotinamide methylase, EC 2.1.1.1) in normal tissues from adult rat and mouse and in tumors and the change in the enzyme activity during the the development of rat tissues were studied. (1) Rat liver exhibited the highest nicotinamide methylase activity among all adult tissues tested; other rat tissues, like adrenal, pancreas, kidney, brain and mouse tissues, had only less than 15% of the adult rat liver activity. (2) 3 days before birth, fetal liver showed a very low nicotinamide methylase activity (2% of adult rat liver), which, however, increased already 1 day before birth and reached the adult level on the day 28 after birth. (3) In a variety of hepatomas and ascites tumors, an inverse correlation, with some exceptions, between tumor growth rate and nicotinamide methylase activity could be seen. In all hepatomas, with the exception of Morris hepatoma 5123tc, nicotinamide methylase activity was significantly decreased in comparison to normal adult rat liver. The highly malignant Zajdela hepatoma, Yoshida sarcoma, sarcoma 180 and Ehrlich ascites tumor methylated nicotinamide only at a negligibly low rate. (4) Cultured RLC cells (an established rat liver cell line) from the stationary growth phase or G₁-arrested RLC cells had about half of the adult rat liver activity, yet the activity was 70% higher than that of the logarithmically growing RLC cells.     

Cholecystokinin and vasoactive intestinal peptide in brain and gut of the hypothyroid neonatal rat

The rat has been a useful model for studying neuronal and metabolic abnormalities associated with fetal and neonatal hypothyroidism produced by treatment of the mother with antithyroid medication. The neonates are then maintained on this medication via the mother's milk until weaning and subsequently through the drinking water. We have determined the concentrations and contents of immunoreactive cholecystokinin (CCK) and vasoactive intestinal peptide (VIP) in the brain and gut of groups of rats exposed to antithyroid medication from day 16 of gestation. The neonates were sacrificed at 2, 4, 8 and 12 weeks. Compared to controls total body weight was greatly reduced in methimazole (MMI)-treated rats, all of whom were hypothyroid as evidenced by marked reduction of T4 and increase in TSH. Discontinuation of MMI-treatment after 8 weeks resulted in normalization of T4 and TSH and a dramatic weight gain but at 12 weeks the brain weights of the MMI-treated rats were reduced by 17% and the brain contents, of CCK and VIP were similarly reduced. Tissue weights throughout the gut were 1/2 or less than those of control rats. Since VIP but not CCK concentrations in the gut of MMI-treated animals were significantly greater than those of the control animals, it would appear that there was greater loss of mucosal tissue with its endocrine content of CCK than of neuronal tissue with its greater content of VIP.(ABSTRACT TRUNCATED AT 250 WORDS)     

Alteration of apoptotic protease-activating factor-1 (APAF-1)-dependent apoptotic pathway during development of rat brain and liver.

Brain and liver extracts of rats at different stages after birth were examined for cytochrome c/dATP-dependent caspase (DEVDase)-activation (mitochondria pathway) in vitro. The caspase-activating activity in the brain extracts rapidly decreased after birth, reaching approximately 50 and 5%, at 1 and 2 weeks, respectively, of that in a 3-days- newborn sample, and essentially no caspase-activation was detected in the adult rat brain extracts. Such a dramatic change was not detected in the liver samples, suggesting that the observed abrogation of the cytochrome c-dependent mitochondria pathway after birth is a brain-specific event. In order to determine the factor(s) lacking in adult brain, we separately measured Apaf-1, procaspase 9, and pro-DEVDase activities using a supplementation assay. In adult brain, Apaf-1 activity was scarcely detected, while the tissue retained low but significant amounts of procaspase 9 (16% of that in the fetal tissue) and a pro-DEVDase (3.4%). In contrast, adult liver extracts retained relatively high levels of all of these factors. Immunoblot analyses clearly indicated that the expression of Apaf-1 and procaspase 3 is markedly suppressed within 4 weeks after birth in brain tissue while they are even expressed in adult liver. Considering these results together, we propose that, in the brain, the cytochrome c-dependent mitochondria pathway, which is essential for the programmed cell death during normal morphogenesis, is abrogated within 2-4 weeks after birth, whereas the pathway is still active in other adult tissues such as liver.     

D-aspartate oxidase, a peroxisomal enzyme in liver of rat and man

By means of subcellular fractionation D-aspartate oxidase was shown to be localized in peroxisomes in rat and human liver. The oxidase from both sources was most active on D-aspartate and N-methyl-D-aspartate. In different rat tissues, the highest enzyme activity was found in kidney, followed by liver and brain. In these tissues, oxidase activities became detectable 1-4 days after birth, reaching adult values after 4 weeks. Analysis of liver samples from patients with Zellweger syndrome, a generalized peroxisomal dysfunction, demonstrated no significant deficiency of this particular oxidase.     

Immunocytochemistry and in situ hybridization studies of pepsinogen C-producing cells in developing rat fundic glands

The ontogeny of pepsinogen C-producing cells in rat fundic glands was studied by means of light and electron microscopy using an antiserum raised against a synthetic peptide based on rat pepsinogen C. To confirm the immunocytochemistry results, the expression of rat pepsinogen C messenger RNA (mRNA) in the fundic gland was also examined by in situ hybridization using a digoxigenin-labeled RNA probe. In adult rats, pepsinogen C was produced by chief cells, mucous neck cells, and intermediate mucopeptic cells. Pepsinogen C-producing cells appeared in embryos as early as 18.5 days’ gestation. The development of these cells could be classified into four stages: (1) 18.5 days’ gestation to 0.5 days after birth; (2) 0.5 days to 2 weeks after birth; (3) 3–4 weeks after birth; (4) 4–8 weeks after birth. In embryos and young animals, pepsinogen C-producing cells were mucopeptic cells. By 4 weeks after birth, mucous neck cells could be distinguished morphologically. The maturation stages of the chief cells could be traced by electron microscopy along the longitudinal axis of the rat fundic gland by double-staining with anti-pepsinogen C antibody and periodic acid-thiocarbohydrazide-silver proteinate. Positive reactions for pepsinogen C and pepsinogen C mRNA expression were detected in mucous neck cells. Therefore, we conclude that mucous neck cells are precursor cells of chief cells. Mucous neck cells, intermediate cells, and chief cells are in the same differentiating cell lineage.     

Ontogeny of the GTP-Binding Protein Go in Rat Brain and Heart

We determined the ontogeny of the GTP-binding protein Go in rat brain and heart by employing highly sensitive enzyme immunoassay methods. In the brain, the alpha subunit of Go (Go alpha) gradually increased and reached adult levels approximately 20 and 30 days after birth in cerebral cortex and cerebellum, respectively. Concentrations of beta subunits, which were also quantified by the immunoassay, were almost equal to those of Go alpha in the brain of rats younger than 10 days, but were higher than those of Go alpha after 10 days. These results suggest that late development of GTP-binding proteins other than Go. Go alpha was immunohistochemically positive in neuropils and negative in cell bodies at any age tested. In the heart, the concentrations of Go alpha increased up to several times of the adult level just after birth, and then gradually decreased after the 20th postnatal day. The level of Go alpha in the liver, however, was very low and constant throughout ontogenic development. An immunohistochemical study indicated that Go alpha was positive in the cardiac muscle of young rat, but negative in that of adult rat. These results indicate that Go alpha exists in cells other than those of nervous tissues and neuroendocrine cells in some periods of ontogenic development.     

Variation in the amounts of hepatic copper, zinc and metallothionein mRNA during development in the rat.

Amounts of hepatic metallothionein mRNA were assessed in RNA from foetal and neonatal rat livers by using dot-blot hybridization. Metallothionein mRNA began to increase about day 15 of gestation and reached a foetal maximum of 5-fold higher than adult values between 18 and 21 days of gestation. The amounts fell significantly for the first 3 days after parturition, and rose again to 6-fold above adult values 6 days after birth. By 15 days after birth the metallothionein mRNA had declined to adult amounts. In comparison, amounts of ornithine transcarbamoylase mRNA did not vary greatly during development. Hepatic zinc concentrations increased from day 14 of gestation to a maximum just before birth, and remained above adult values until 30 days after birth. From 14 days of gestation to 8 days after birth, hepatic copper concentrations were about 4-fold higher than in the adult, but a substantial increase (to about 9-fold higher than in the adult) occurs between 10 and 15 days after birth. CdCl2 administered to pregnant rats on day 18 of gestation was shown to block placental transfer of zinc, and we found decreased foetal hepatic zinc concentration after the CdCl2 treatment, but this failed to cause a significant decrease in metallothionein mRNA, suggesting that zinc may not be the primary inducer of hepatic metallothionein mRNA during foetal life.     

Prenatal and postnatal changes in the content and species of ferritin in rat liver

The iron and ferritin content of rat liver and the species of ferritin present were examined from 4 days before to 3 weeks after birth. 1. Total iron and ferritin iron accumulated rapidly during the last days of gestation and from the second postnatal day underwent a steady depletion. 2. The amount of iron deposited before birth in the liver of each pup varied inversely with litter size and could be increased moderately by injection of iron into the mother before mating. 3. Intraperitoneal injection of iron 1 day after birth doubled the concentration of total iron, ferritin iron and ferritin protein in the liver over the next 24h, but at 3 weeks after birth it raised the very low concentrations of iron and ferritin severalfold. 4. As shown by electrophoretic migration, ferritin and dissociated ferritin subunits prepared from the livers of rats from 4 days before to 3 weeks after birth differed from those of adult liver ferritin and were indistinguishable from those of adult kidney and spleen ferritin. Treatment with iron at 3 weeks of age induced formation of a ferritin with electrophoretic properties resembling those of adult liver. It is concluded that iron given at this stage of development may activate the genetic cistron for adult liver ferritin.     

Ornithine Decarboxylase Activity in Brain Regulated by a Specific Macromolecul, the Antizyme

Mouse brain ornithine decarboxylase activity is about 70-fold higher at the time of birth compared with that of adult mice. Enzyme activity declines rapidly after birth and reaches the adult level by 3 weeks. Immunoreactive enzyme concentration parallels very closely the decrease of enzyme activity during the first postnatal week, remaining constant thereafter. The content of brain antizyme, the macromolecular inhibitor to ornithine decarboxylase, in turn is very low during the first 7 days and starts then to increase and at the age of 3 weeks it is about six times the level of that in newborn mice. This may explain the decrease in enzyme activity during brain maturation, and suggests the regulation of polyamine biosynthesis by an antizyme-mediated mechanism in adult brain.     

Brain cholecystokinin in fasted and fed mice

Immunoreactive cholecystokinin (iCCK) in brain extracts is reduced to 133 ± 6 ng/g from 274 ± ng/g in 2 to 5 day fasted C₃H mice. Brain weights of fed and fasted mice do not differ although the body weights of fasted mice averaged only about two-thirds of the fed weights. Since the cortex contains over 80% of the brain iCCK in fed mice, it is concluded that food-deprivation is associated with decreased synthesis of cortical iCCK.     

Development of mitochondrial energy metabolism in rat brain

1. The development of pyruvate dehydrogenase and citrate synthase activity in rat brain mitochondria was studied. Whereas the citrate synthase activity starts to increase at about 8 days after birth, that of pyruvate dehydrogenase starts to increase at about 15 days. Measurements of the active proportion of pyruvate dehydrogenase during development were also made. 2. The ability of rat brain mitochondria to oxidize pyruvate follows a similar developmental pattern to that of the pyruvate dehydrogenase. However, the ability to oxidize 3-hydroxybutyrate shows a different developmental pattern (maximal at 20 days and declining by half in the adult), which is compatible with the developmental pattern of the ketone-body-utilizing enzymes. 3. The developmental pattern of both the soluble and the mitochondrially bound hexokinase of rat brain was studied. The total brain hexokinase activity increases markedly at about 15 days, which is mainly due to an increase in activity of the mitochondrially bound form, and reaches the adult situation (approx. 70% being mitochondrial) at about 30 days after birth. 4. The release of the mitochondrially bound hexokinase under different conditions by glucose 6-phosphate was studied. There was insignificant release of the bound hexokinase in media containing high KCl concentrations by glucose 6-phosphate, but in sucrose media half-maximal release of hexokinase was achieved by 70μm-glucose 6-phosphate 5. The production of glucose 6-phosphate by brain mitochondria in the presence of Mg²⁺+glucose was demonstrated, together with the inhibition of this by atractyloside. 6. The results are discussed with respect to the possible biological significance of the similar developmental patterns of pyruvate dehydrogenase and the mitochondrially bound kinases, particularly hexokinase, in the brain. It is suggested that this association may be a mechanism for maintaining an efficient and active aerobic glycolysis which is necessary for full neural expression.     

Glycosaminoglycans of brain during development.

The concentration of hyaluronic acid, chondroitin sulfate, and heparan sulfate was measured in rat brain at 2-day intervals from birth to 1 month of age, and in 40-day-old and adult animals. The levels of all three glycosaminoglycans increased after birth to reach a peak at 7 days after which they declined steadily, attaining by 30 days concentrations within 10% of those present in adult brain. The greatest change was seen in hyaluronic acid, which decreased by 50% in 3 days, and declined to adult levels (28% of the peak concentration) by 18 days of age. Only heparan sulfate showed a significant change in metabolic activity during development (a fourfold increase in the relative specific activity of glucosamine), most of which occurred after 1 week of age. In 7-day-old rats almost 90% of the hyaluronic acid in brain is extractable by water alone, as compared to only 15% in adult animals, and this large amount of soluble hyaluronic acid in young rat brain is relatively inactive metabolically. On the basis of our data we propose that the higher amounts of hyaluronic acid found in very young brain may be responsible for the higher water content of brain at these ages, and that the hydrated hyaluronic acid serves as a matrix through which neuronal migration and differentiation may take place during early brain development.     

Uridine kinase activities in developing, adult and neoplastic rat tissues.

Uridine kinase activities were found chiefly in the soluble fractions of rat tissues. In normal adults the activities ranged from 13 munits/g in skeletal muscle to 178 munits/g in colon. Enzyme activities in several rat neoplasms were significantly higher (e.g. in a fibrosarcoma, mammary carcinoma, renal carcinoma, pancreatic carcinoma and lymphocytic lymphoma, but not in a fast-growing Morris hepatoma). The activities were not related to tumour growth rates or sizes. In normal foetal liver, lung, brain, heart and kidney, uridine kinase concentrations equalled or exceeded those in the adult homologous tissue, but maximal activities in liver were reached 3--5 days post partum. In suckling rats the intestinal activity decreased substantially immediately after birth and normally did not rise again until late in the third postnatal week. Premature upsurges could be evoked by an injection of cortisol or by starvation of the pups overnight. Pancreatic activity was absent from 1-day-old rats, and only about 5% of the adult activity was reached by day 20; adult activities were attained rapidly after weaning. In pancreas, precocious formation or uridine kinase was elicited by overnight starvation of 2-week-old rats.     

Hepatic and extrahepatic N-acetyltransferase. Perinatal development using a new radioassay.

We report a sensitive and rapid radioassay method for p-aminobenzoic acid N-acetyltransferase. The principle of this assay involves acetylation of p-aminobenzoic acid with [1-14C] labeled acetyl coenzyme A and direct extraction of enzymically formed radioactive p-acetamidobenzoic acid into nonaqueous scintillation fluid. Using this radiometric assay, hepatic and extrahepatic tissue distributions from rat and rabbit were studied. Rabbit blastocyst and endometrial N-acetyltransferase specific activities were equivalent to hepatic activities. Perinatal development studies in rats and rabbits revealed that fetal and neonatal animals are capable of N-acetylation. Rat liver developmental studies exhibited two peaks of activity with the first peak occurring in the late fetus followed by a second peak 3 days after birth. Rabbit fetal and neonatal enzyme activity increased to adult levels by the second week after birth in liver and gut, however, lung showed a different developmental pattern. These studies demonstrate that fetal extrahepatic tissues, like adult tissues, play an important role in N-acetylation.     

Tissue distribution and developmental expression of protein kinase C isozymes

Protein kinase C is a ubiquitous enzyme found in a variety of mammalian tissues and is especially highly enriched in brain and lymphoid organs. Based on biochemical and immunological analyses, we have identified three types of protein kinase C isozyme (designated types I-III) from rat brain. Monospecific antibodies against each of the protein kinase C isozymes were prepared for the determination of tissue distribution, subcellular localization, and developmental changes of these enzymes. The various protein kinase C isozymes were found to be distinctively distributed in different tissues: the type I enzyme in brain; the type II enzyme in brain, pituitary and pineal glands, spleen, thymus, retina, lung, and intestine; and the type III enzyme in brain, pineal gland, retina, and spleen. The rat brain enzymes were differentially distributed in different subcellular fractions. The type I enzyme appeared to be most lipophilic and was recovered mostly in the particulate fractions (80-90%) regardless of the EGTA- or Ca2+-containing buffer used in the homogenization. Significant amounts (30-40%) of the type II and III enzymes were recovered in the cytosolic fraction with EGTA-containing buffer. The expressions of different protein kinase C isozymes appear to be differently controlled during development. In rat brain, both type II and III enzymes were found to increase progressively from 3 days before birth up to 2-3 weeks of age and remained constant thereafter. However, the expression of the type I enzyme displayed a different developmental pattern; it was very low within 1 week, and an abrupt increase was observed between 2 and 3 weeks of age. In thymus, the type II enzyme was found to be maximal shortly after birth; whereas the same kinase in spleen was very low within 2 weeks of age, and a significant increase was observed between 2 and 3 weeks. These results demonstrate that protein kinase C isozymes are distinctively distributed in different tissues and subcellular locales and that their expressions are controlled differently during development.     

Effect of sex hormones on plasma T-kininogen in the rat

The influence of sex hormones on rat plasma T-kininogen concentration was examined. The level of T-kininogen in the post-pubertal female rat is about 3-times that of the male animal. Female rats castrated as adults or 15 days after birth, had low T-kininogen concentrations, near those of male rats. In contrast, castration of mature or immature male animals induced no change in T-kininogen. Treatment of castrated female or male rats with 17 alpha-ethinylestradiol significantly increased the T-kininogen level, whereas administration of testosterone or progesterone had no effect. The influence of estrogen was specific for T-kininogen, since plasma HMW kininogen concentration was the same in male and female rats and was not affected by castration or sex hormone treatment. T-kininogen concentration was not significantly changed in pregnant rat between the 12th and the 20th day of pregnancy, but increased after parturition. It was high in the newborn rat at birth and then decreased similarly over the next 3 weeks in males and females. It continued to decrease in the males, reaching the level of the adult rat, but it increased in the female from 3-4 weeks of age and reached the adult level at about 6-8 weeks. These data indicate that natural estrogens have a physiological influence on the plasma level of T-kininogen in female rats whereas testosterone had no effect on either male or castrated female rats. HMW kininogen is not physiologically dependent on sex hormones.     

DOPAMINE-β-HYDROXYLASE IN THE RAT BRAIN: DEVELOPMENTAL CHARACTERISTICS

Abstract— A sensitive and specific assay for dopamine-8-hydroxylase (DBH) in the rat brain has been developed. The enzyme in the brain has requirements for cofactors and affinity for substrate similar to DBH in the adrenal medulla. DBH activity was demonstrable in the brain of the fetal rat at 15 days of gestation; there was an increase in DBH activity with maturation that preceded and paralleled the rise in levels of endogenous norepinephrine until 3 weeks after birth. There was a shift in the distribution of total DBH activity from the caudal to the rostral regions of the brain during development. In the adult brain, DBH was highly localized in the nerve terminals. Between 17 days of gestation and adult-hood, there was 2300-fold increase in the DBH activity that sedimented with sheared-off nerve terminals.     

The Development of Enzymes of Energy Metabolism in the Brain of a Precocial (Guinea Pig) and Non-Precocial (Rat) Species

Abstract: Key enzymes of ketone body metabolism (3-hydroxybutyrate de-hydrogenase, 3-oxo-acid: CoA transferase, acetoacetyl-CoA thiolase) and glucose metabolism (hexokinase, lactate dehydrogenase, pyruvate dehydrogenase, citrate synthase) have been measured in the brains of foetal, neonatal and adult guinea pigs and compared to those in the brains of neonatal and adult rats. The activities of the guinea pig brain ketone-body-metabolising enzymes remain relatively low in activity throughout the foetal and neonatal periods, with only slight increases occurring at birth. This contrasts with the rat brain, where three- to fourfold increases in activity occur during the suckling period (0–21 days post partum), followed by a corresponding decrease in the adult. The activities of the hexokinase (mitochondrial and cytosolic), pyruvate dehydrogenase, lactate dehydrogenase and citrate synthase of guinea pig brain show marked increases in the last 10–15 days before birth, so that at birth the guinea pig possesses activities of these enzymes similar to the adult state. This contrasts with the rat brain where these enzymes develop during the late suckling period (10–15 days after birth). The development of the enzymes of aerobic glycolytic metabolism correlate with the onset of neurological competence in the two species, the guinea pig being a "precocial" species born neurologically competent and the rat being a "non-precocial" species born neurologically immature. The results are discussed with respect to the enzymatic activities required for the energy metabolism of a fully developed, neurologically competent mammalian brain and its relative sensitivity to hypoxia.